#include #include #include #include #include #include #include #include "websocket.h" #include "network.h" #define RFC6455_MAGIC_KEY "258EAFA5-E914-47DA-95CA-C5AB0DC85B11" #define WS_FRAME_HEADER_LEN 16 #define WS_FLAG_FIN 0x80 #define WS_GET_FIN(a) (((a) & WS_FLAG_FIN) >> 7) #define WS_GET_RESERVED(a) (((a) & 0xE0) >> 4) #define WS_GET_OP(a) ((a) & 0x0F) #define WS_GET_MASK(a) (((a) & 0x80) >> 7) #define WS_GET_LEN(a) ((a) & 0x7F) /* * Close and shut down a WebSocket connection, including a connected * peer stream. Frees all resources associated with either connection. */ int ws_close(websocket* ws, ws_close_reason code, char* reason){ size_t p; ws_peer_info empty_peer = { 0 }; if(ws->state == ws_open && reason){ //send close frame //FIXME this should prepend the status code to the reason ws_send_frame(ws, ws_frame_close, (uint8_t*) reason, strlen(reason)); } else if(ws->state == ws_http && code == ws_close_http && reason){ //send http response network_send_str(ws->ws_fd, "HTTP/1.1 "); network_send_str(ws->ws_fd, reason); network_send_str(ws->ws_fd, "\r\n\r\n"); } ws->state = ws_closed; if(ws->ws_fd >= 0){ close(ws->ws_fd); ws->ws_fd = -1; } if(ws->peer_fd >= 0){ close(ws->peer_fd); ws->peer_fd = -1; //clean up framing data if(ws->peer_framing_data){ ws->peer.framing(NULL, 0, 0, NULL, &(ws->peer_framing_data), ws->peer.framing_config); ws->peer_framing_data = NULL; } } for(p = 0; p < ws->headers; p++){ free(ws->header[p].tag); ws->header[p].tag = NULL; free(ws->header[p].value); ws->header[p].value = NULL; } ws->headers = 0; for(p = 0; p < ws->protocols; p++){ free(ws->protocol[p]); } free(ws->protocol); ws->protocol = NULL; ws->protocols = 0; ws->read_buffer_offset = 0; ws->peer_buffer_offset = 0; free(ws->request_path); ws->request_path = NULL; free(ws->socket_key); ws->socket_key = NULL; ws->websocket_version = 0; ws->want_upgrade = 0; free(ws->peer.host); free(ws->peer.port); free(ws->peer.framing_config); ws->peer = empty_peer; return 0; } /* Accept a new WebSocket connection */ int ws_accept(int listen_fd, time_t current_time){ websocket ws = { .ws_fd = accept(listen_fd, NULL, NULL), .peer_fd = -1, .last_event = current_time }; return client_register(&ws); } /* Handle data in the NEW state (expecting a HTTP negotiation) */ static int ws_handle_new(websocket* ws){ size_t u; char* path, *proto; if(!strncmp((char*) ws->read_buffer, "GET ", 4)){ path = (char*) ws->read_buffer + 4; for(u = 0; path[u] && !isspace(path[u]); u++){ } path[u] = 0; proto = path + u + 1; } //TODO handle other methods else{ fprintf(stderr, "Unknown HTTP method in request\n"); return 1; } if(strncmp(proto, "HTTP/", 5)){ fprintf(stderr, "Malformed HTTP initiation\n"); return 1; } ws->state = ws_http; ws->request_path = strdup(path); return 0; } /* Handle end of HTTP header data and upgrade the connection */ static int ws_upgrade_http(websocket* ws){ if(ws->websocket_version == 13 && ws->socket_key && ws->want_upgrade == 3){ //find and connect peer if(client_connect(ws)){ ws_close(ws, ws_close_http, "500 Peer connection failed"); return 0; } if(network_send_str(ws->ws_fd, "HTTP/1.1 101 Upgrading\r\n") || network_send_str(ws->ws_fd, "Upgrade: websocket\r\n") || network_send_str(ws->ws_fd, "Connection: Upgrade\r\n")){ ws_close(ws, ws_close_http, NULL); return 0; } //calculate the websocket accept key, which for some reason is defined (RFC 4.2.2.5.4) as //base64(sha1(concat(trim(client-key), "258EAFA5-E914-47DA-95CA-C5AB0DC85B11"))) //requiring not one but 2 unnecessarily complex operations size_t encode_offset = 0; struct sha1_ctx ws_accept_ctx; struct base64_encode_ctx ws_accept_encode; uint8_t ws_accept_digest[SHA1_DIGEST_SIZE]; char ws_accept_key[BASE64_ENCODE_LENGTH(SHA1_DIGEST_SIZE) + 3] = ""; sha1_init(&ws_accept_ctx); sha1_update(&ws_accept_ctx, strlen(ws->socket_key), (uint8_t*) ws->socket_key); sha1_update(&ws_accept_ctx, strlen(RFC6455_MAGIC_KEY), (uint8_t*) RFC6455_MAGIC_KEY); sha1_digest(&ws_accept_ctx, sizeof(ws_accept_digest), (uint8_t*) &ws_accept_digest); base64_encode_init(&ws_accept_encode); encode_offset = base64_encode_update(&ws_accept_encode, (char*) ws_accept_key, SHA1_DIGEST_SIZE, ws_accept_digest); encode_offset += base64_encode_final(&ws_accept_encode, (char*) ws_accept_key + encode_offset); memcpy(ws_accept_key + encode_offset, "\r\n\0", 3); //send websocket accept key if(network_send_str(ws->ws_fd, "Sec-WebSocket-Accept: ") || network_send_str(ws->ws_fd, ws_accept_key)){ ws_close(ws, ws_close_http, NULL); return 0; } //acknowledge selected protocol if(ws->peer.protocol < ws->protocols){ if(network_send_str(ws->ws_fd, "Sec-WebSocket-Protocol: ") || network_send_str(ws->ws_fd, ws->protocol[ws->peer.protocol]) || network_send_str(ws->ws_fd, "\r\n")){ ws_close(ws, ws_close_http, NULL); return 0; } } ws->state = ws_open; if(network_send_str(ws->ws_fd, "\r\n")){ ws_close(ws, ws_close_http, NULL); return 0; } return 0; } //RFC 4.2.2.4: An unsupported version must be answered with HTTP 426 if(ws->websocket_version != 13){ ws_close(ws, ws_close_http, "426 Unsupported protocol version"); return 0; } return 1; } /* Handle incoming HTTP header lines */ static int ws_handle_http(websocket* ws){ char* header, *value; ssize_t p; if(!ws->read_buffer[0]){ return ws_upgrade_http(ws); } else if(isspace(ws->read_buffer[0])){ //i hate header folding ws_close(ws, ws_close_http, "500 Header folding"); return 0; } else{ header = (char*) ws->read_buffer; value = strchr(header, ':'); if(!value){ ws_close(ws, ws_close_http, "500 Header format"); return 0; } *value = 0; value++; for(; isspace(*value); value++){ } } //RFC 4.2.1 checks if(!strcmp(header, "Sec-WebSocket-Version")){ ws->websocket_version = strtoul(value, NULL, 10); } else if(!strcmp(header, "Sec-WebSocket-Key")){ //right-trim the key for(p = strlen(value) - 1; p >= 0 && isspace(value[p]); p--){ value[p] = 0; } ws->socket_key = strdup(value); } else if(!strcmp(header, "Upgrade") && !strcasecmp(value, "websocket")){ ws->want_upgrade |= 1; } else if(!strcmp(header, "Connection") && strstr(xstr_lower(value), "upgrade")){ ws->want_upgrade |= 2; } else if(!strcmp(header, "Sec-WebSocket-Protocol")){ //parse websocket protocol offers for(value = strtok(value, ","); value; value = strtok(NULL, ",")){ //ltrim for(; *value && isspace(*value); value++){ } //rtrim for(p = strlen(value) - 1; p >= 0 && isspace(value[p]); p--){ value[p] = 0; } for(p = 0; p < ws->protocols; p++){ if(!strcmp(ws->protocol[p], value)){ break; } } //add new protocol if(p == ws->protocols){ ws->protocol = realloc(ws->protocol, (ws->protocols + 1) * sizeof(char*)); if(!ws->protocol){ fprintf(stderr, "Failed to allocate memory\n"); return 1; } ws->protocol[ws->protocols] = strdup(value); ws->protocols++; } } } else if(ws->headers < WS_HEADER_LIMIT){ ws->header[ws->headers].tag = strdup(header); ws->header[ws->headers].value = strdup(value); ws->headers++; } else{ //limit the number of stored headers to prevent abuse //ws_close(ws, ws_close_http, "500 Header limit"); } return 0; } //returns bytes handled static size_t ws_frame(websocket* ws){ size_t u; uint64_t payload_length = 0; uint16_t* payload_len16 = (uint16_t*) (ws->read_buffer + 2); uint64_t* payload_len64 = (uint64_t*) (ws->read_buffer + 2); uint8_t* masking_key = NULL, *payload = ws->read_buffer + 2; //need at least the header bits if(ws->read_buffer_offset < 2){ return 0; } if(WS_GET_RESERVED(ws->read_buffer[0])){ //reserved bits set without any extensions //RFC 5.2 says we MUST close the connection //ignoring it for now } //calculate the payload length from one of 3 cases (RFC 5.2) //could've used a uint64 and be done with it... payload_length = WS_GET_LEN(ws->read_buffer[1]); if(WS_GET_MASK(ws->read_buffer[1])){ if(ws->read_buffer_offset < 6){ return 0; } masking_key = ws->read_buffer + 2; payload = ws->read_buffer + 6; } if(payload_length == 126){ //16-bit payload length if(ws->read_buffer_offset < 4){ return 0; } payload_length = htobe16(*payload_len16); payload = ws->read_buffer + 4; if(WS_GET_MASK(ws->read_buffer[1])){ if(ws->read_buffer_offset < 8){ return 0; } masking_key = ws->read_buffer + 4; payload = ws->read_buffer + 8; } } else if(payload_length == 127){ //64-bit payload length if(ws->read_buffer_offset < 10){ return 0; } payload_length = htobe64(*payload_len64); payload = ws->read_buffer + 10; if(WS_GET_MASK(ws->read_buffer[1])){ if(ws->read_buffer_offset < 14){ return 0; } masking_key = ws->read_buffer + 10; payload = ws->read_buffer + 14; } } //check for complete WS frame if(ws->read_buffer_offset < (payload - ws->read_buffer) + payload_length){ //fprintf(stderr, "Incomplete payload: offset %lu, want %lu\n", ws->read_buffer_offset, (payload - ws->read_buffer) + payload_length); return 0; } //RFC Section 5.1: If the client sends an unmasked frame, close the connection if(!WS_GET_MASK(ws->read_buffer[1])){ ws_close(ws, ws_close_proto, "Unmasked client frame"); return 0; } //unmask data if(WS_GET_MASK(ws->read_buffer[1])){ for(u = 0; u < payload_length; u++){ payload[u] = payload[u] ^ masking_key[u % 4]; } } //TODO handle fragmentation //TODO handle control frames within fragmented frames /*fprintf(stderr, "Incoming websocket data: %s %s OP %02X LEN %u %lu\n", WS_GET_FIN(ws->read_buffer[0]) ? "FIN" : "CONT", WS_GET_MASK(ws->read_buffer[1]) ? "MASK" : "CLEAR", WS_GET_OP(ws->read_buffer[0]), WS_GET_LEN(ws->read_buffer[1]), payload_length);*/ //handle data switch(WS_GET_OP(ws->read_buffer[0])){ case ws_frame_text: //fprintf(stderr, "Text payload: %.*s\n", (int) payload_length, (char*) payload); case ws_frame_binary: //forward to peer if(ws->peer_fd >= 0){ //fprintf(stderr, "WS -> Peer %lu bytes\n", payload_length); if(network_send(ws->peer_fd, payload, payload_length)){ ws_close(ws, ws_close_unexpected, "Failed to forward"); } } break; case ws_frame_close: ws_close(ws, ws_close_normal, "Client requested termination"); break; case ws_frame_ping: if(ws_send_frame(ws, ws_frame_pong, payload, payload_length)){ ws_close(ws, ws_close_unexpected, "Failed to send pong"); } break; case ws_frame_pong: //TODO keep-alive pings break; default: //unknown frame type received fprintf(stderr, "Unknown WebSocket opcode %02X in frame\n", WS_GET_OP(ws->read_buffer[0])); ws_close(ws, ws_close_proto, "Invalid opcode"); break; } return ((payload - ws->read_buffer) + payload_length); } /* Construct and send a WebSocket frame */ int ws_send_frame(websocket* ws, ws_operation opcode, uint8_t* data, size_t len){ //fprintf(stderr, "Peer -> WS %lu bytes (%02X)\n", len, opcode); uint8_t frame_header[WS_FRAME_HEADER_LEN]; size_t header_bytes = 2; uint16_t* payload_len16 = (uint16_t*) (frame_header + 2); uint64_t* payload_len64 = (uint64_t*) (frame_header + 2); //set up the basic frame header frame_header[0] = WS_FLAG_FIN | opcode; if(len <= 125){ frame_header[1] = len; } else if(len <= 0xFFFF){ frame_header[1] = 126; *payload_len16 = htobe16(len); header_bytes += 2; } else{ frame_header[1] = 127; *payload_len64 = htobe64(len); header_bytes += 8; } if(network_send(ws->ws_fd, frame_header, header_bytes) || network_send(ws->ws_fd, data, len)){ return 1; } return 0; } /* Handle incoming data on a WebSocket client */ int ws_data(websocket* ws){ ssize_t bytes_read, n, bytes_left = sizeof(ws->read_buffer) - ws->read_buffer_offset; int rv = 0; bytes_read = recv(ws->ws_fd, ws->read_buffer + ws->read_buffer_offset, bytes_left - 1, 0); if(bytes_read < 0){ fprintf(stderr, "Failed to receive from websocket: %s\n", strerror(errno)); ws_close(ws, ws_close_unexpected, NULL); return 0; } else if(bytes_read == 0){ //client closed connection ws_close(ws, ws_close_unexpected, NULL); return 0; } //terminate new data ws->read_buffer[ws->read_buffer_offset + bytes_read] = 0; switch(ws->state){ case ws_new: case ws_http: //scan for newline, handle line for(n = 0; n < bytes_read - 1; n++){ if(!strncmp((char*) ws->read_buffer + ws->read_buffer_offset + n, "\r\n", 2)){ //terminate line ws->read_buffer[ws->read_buffer_offset + n] = 0; if(ws->state == ws_new){ ws_handle_new(ws); } else{ ws_handle_http(ws); } //remove from buffer bytes_read -= (n + 2); memmove(ws->read_buffer, ws->read_buffer + ws->read_buffer_offset + n + 2, bytes_read); ws->read_buffer_offset = 0; //restart from the beginning n = -1; } } //update read buffer offset ws->read_buffer_offset = bytes_read; break; case ws_open: ws->read_buffer_offset += bytes_read; for(n = ws_frame(ws); n > 0 && ws->read_buffer_offset > 0; n = ws_frame(ws)){ memmove(ws->read_buffer, ws->read_buffer + n, ws->read_buffer_offset - n); ws->read_buffer_offset -= n; } break; //this should never be reached, as ws_close also closes the client fd case ws_closed: fprintf(stderr, "This should not have happened\n"); break; } //disconnect spammy clients if(sizeof(ws->read_buffer) - ws->read_buffer_offset < 2){ fprintf(stderr, "Disconnecting misbehaving client\n"); ws_close(ws, ws_close_limit, "Receive size limit exceeded"); return 0; } return rv; }